US3340077A - Fused cast refractory - Google Patents

Fused cast refractory Download PDF

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US3340077A
US3340077A US434812A US43481265A US3340077A US 3340077 A US3340077 A US 3340077A US 434812 A US434812 A US 434812A US 43481265 A US43481265 A US 43481265A US 3340077 A US3340077 A US 3340077A
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group
refractory
metallic
crystals
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Allen M Alper
Robert C Doman
Robert N Mcnally
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Corning Glass Works
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Corning Glass Works
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Priority to NO159550A priority patent/NO119468B/no
Priority to GB37371/65A priority patent/GB1101854A/en
Priority to NL6511776A priority patent/NL6511776A/xx
Priority to AT829765A priority patent/AT276203B/de
Priority to DE19651571358 priority patent/DE1571358A1/de
Priority to SE11847/65A priority patent/SE305621B/xx
Priority to BE669498D priority patent/BE669498A/xx
Priority to ES0317367A priority patent/ES317367A1/es
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Definitions

  • This invention relates to monolithic refractory ceramic blocks or articles of manufacture commonly known as fused cast refractory.
  • This type of refractory article is most customarily produced by melting refractory ceramic raw material and pouring the molten material into a preformed mold to solidify as a monolithic casting therein. It is also known that in some cases fused cast refractory can be produced by solidifying the molten material in situ within the crucible or furnace container in which it was melted.
  • the invention relates to novel fused cast refractory comprising free carbon intermingling with metallic boride crystals and/ or borocarbide (or carboboride) crystals such that the refractory exhibits highly superior resistance to thermal or heat shock and, in most cases, has unusually excellent oxidation resistance at temperatures as high as about 1000 C. or more.
  • another aspect of the invention relates to such novel fused cast refractory that exhibits excellent resistance to corrosion and erosion by molten ferrous metal and the ferruginous lime slags in reducing atmosphere environments as is commonly found in the basic oxygen steelmaking furnace processes, such as the Stora-Kaldo process.
  • slags usually have a lime-silica ratio of 1:1 to 1.5 :1 at the early stage of a heat and the ratio increases toward the end of a heat to usually in excess of 25:1 for the higher lime finishing slags.
  • the reducing atmosphere tends to be predominantly carbon monoxide.
  • refractory is provided with a corrosion resistance that may make it desirable for contacting or containing other molten metals or alloys and their slags, dresses, etc. (e.g. manganese, nickel, cobalt, aluminum, copper, zinc, tin, lead, etc.).
  • prior friable masses of the metal borides or of the metal carbides have been produced with a small excess of carbon in the raw materials forming a minor but undesired contaminating amount of free carbon in these massesarnounting to fractions up to l1 /2% by weight in the borides and somewhat greater (e.g. more commonly 12% by weight) in the carbides.
  • Most efforts were made to eliminate such free carbon contaminant in the granular materials because it caused difficulties in producing proper abrasive or wear resistant products, or the free carbon was further reacted with a carbide-forming element to convert'the carbon to a hard carbide.
  • fused cast refractory bodies of this invention are particularly suitable for forming the working lining of the basic oxygen vessels that conventionally comprise a generally pear-shaped or barrel-shaped metal tank or casing, insulating refractory lining covering the internal surfaces of this tank, working refractory lining covering the internal surfaces of the insulating refractory lining and a watercoo1ed lance or means for providing an oxygen blast directed into the refractory lined tank.
  • the present invention is an article of manufacture that can be generally defined as a fused cast refractory body consisting essentially of at least 7% (or at a very minimum of 2%) by weight free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of metallic boride crystals, metallic borocarbide crystals (i.e.
  • a complex phase of metal-boron-carbon that might also be described as either metallic carbide containing boron in solid solution or metallic boride containing carbon in solid solution, and may alternatively be termed carboboride) and mixtures of these crystals, and the body analytically comprises essentially carbon, more than 5% (desirably at least 10% to assure good oxidation resistance) by weight of boron and more than 5% (desirably at least 10%) by weight of metallic substance as set forth below. While these are the only two or three essential phases and the only three essential analytical components of the monolithic body, limited amounts of other optional phases and/or analytical components (as specified below) may be included as desired and without deleteriously affecting the basic novel properties indicated above. Inclusion of these optional phases and/or analytical components will usuallydepend upon the precise properties desired in the final product,
  • the processing conditions desirably employed and the raw materials that are desired to be used are desirably employed and the raw materials that are desired to be used.
  • the analytical metallic substance can be composed of one or more metallic elements now to be described. Where only a single metallic element is employed to form the crystals of boride and/or borocarbide, this element is selected from the group consisting of titanium, Zirconium, halfnium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten and silicon. Any mixture of two or more of the foregoing metals can also be employed to form one or more physical constituents or phases of metallic boride, of metallic borocarbide and of mixtures thereof, depending upon the degree of mutual solid solution solubility of one such boride or carbide in other borides or carbides.
  • the analytical metallic substance may be composed of mixtures comprising any one or more of the above-described first group of metals plus at least one metallic element selected from a second group consisting of manganese, iron, cobalt and nickel provided the content of the second group metals is not greater than 50% by weight of the total metallic substance content.
  • one or more boride and/or borocarbide phases will also be formed depending upon the degree of mutual solid solution solubility.
  • the optional analytical components permissible in the fused cast refractory according to this invention may be categorized as diluents and/or impurities.
  • Oxygen and nitrogen are here categorized as diluents, although in some cases they may be in a sense deemed impurities while in other cases they may be deemed desirable additives.
  • Each of oxygen and nitrogen should not analytically exceed by weight of the monolithic body or casting and the total sum of oxygen plus nitrogen should not analytically exceed by weight of the body or casting in order to avoid deleteriously affecting the basic novel properties, such as the thermal shock resistance and the corrosionerosion resistance.
  • other elements up to 10% (preferably not more than 5%) by weight as impurities or minor diluent additives.
  • Many of such other elements will commonly result from the use of less pure raw materials and may include (although not limited thereto) elements such as aluminum, alkali metals, alkaline earth metals, rare earth metals, sulfur, phosphorus, etc. Again the limitation on the remainder of these other elements is generally necessary to avoid deleteriously affecting one or more of the basic novel properties.
  • variants of these boride and borocarbide crystals were noted with variations in analytical composition.
  • the variants found are: one or more of simple borides, e.g. TiB or Cr B +CrB; one or more of complex borides comprising in essence a solid solution of two or more simple borides, e.g. (Ti,Cr)B one or more of simple borocarbides, e.g. CI'(B Cy);
  • complex borocarbides comprising in essence a solid solution of two or more simple boro carbides, e.g. (Zr,Hf) (B or mixtures of these four variants.
  • composition systems involving three or more of the metallic substances the existence of very complex crystalline phases and/ or solid solutions are possible and usually likely.
  • additional crystal phases were found in a number of samples, which included boron carbide, metallic carbides and (to a lesser degree) elemental metal or alloy, metallic oxides and/or complex phases containing carbon, oxygen and nitrogen.
  • FIGURES 1 through 8 are photomicrographs (magnification approx. x) showing exemplary microstructures of eight different embodiments or fused cast refractory examples according to this invention.
  • the raw materials can be a mixture of: (1) the appropriate metal (or metals) and/or oxide of the appropriate metal (or metals) plus (2) boron, boric oxide and/or borate, (3) with or without (for the reasons set forth below) a source of carbon (e.g. carbon black, graphite, coke, etc.).
  • a source of carbon e.g. carbon black, graphite, coke, etc.
  • any other suitable raw material mixtures desired can also be employed, e.g. boride and graphite.
  • the mixtures can be readily melted, without excessive loss of material by sublimation and/or vaporization, in either an electric induction melting furnace employing a graphite lining or pot, or in a conventioal electric arc melting furnace employing graphite electrodes in the same manner as is common in producing other fused cast type refractories or in producing calcium carbide.
  • the lining of the furnace shell need not be specially constructed of graphite because the melting operation can be carried out in the customary manner of forming a molten pool contained Within a surrounding mass of unmelted and unreacted and/or partially reacted batch mixture material as a protective liner to prevent contamination of the molten bath.
  • an appropriate loose fitting crown or cover over the top opening of the furnace can be employed to regulate the exhaust of the reducing gases and fume produced during the melting operation so as to substantially prevent ingress of air into the furnace chamber.
  • the molten product in the furnace obtains or derives a substantial amount of its carbon content from the graphite liner or the graphite electrodes (as the case may be) and, therefore, the amount of carbon employed in the batch mixture is kept less than the total amount of a carbon necessary to form the particular composition desired.
  • an appropriate quantity of molten batch material is formed and then the molten mass is quickly poured into graphite molds, which molds are provided with the usual font header and surrounded in the conventional manner with annealing powder, such as alumina powder, powdered coke, etc.
  • annealing powder such as alumina powder, powdered coke, etc.
  • the top of the font header is also covered with annealing powder and the cast molten material is allowed to solidify therein to form a monolithic casting or body of fused cast refractory having the shape of the mold cavity.
  • This procedure produces relatively rapid solidification yielding substantially random shaped boride and/or borocarbide (with or without carbides and minor amounts of oxides and/or oxyborides) crystals or crystalline masses that are substantially (i.e.
  • the free carbon (which in most cases is crystalline graphite) forms an intergrown network intermingling and interlocking with the boride, borocarbide and other crystals or crystal masses.
  • Such a network is in essence most of, or at least the great majority of, the numerous particles, masses or crystals of free carbon (graphite) in the body grown or bonded together (commonly at intersecting points) to form a skeleton of at least semicontinuous nature.
  • This free carbon network or skeleton may be made up of a variety of irregular shaped masses, many of which appear as elongated segments and all of which intermingle within and between the other crystals and crystal masses.
  • larger platelets of graphite additionally appear and form part of the network or skeleton. Together with smaller elongated segments in some cases, these platelets form a random, semicontinuous interwoven pattern or intertexture within and between the mass of other crystals.
  • the interlocking bonding in combination with the intergrown network of free carbon (graphite) is typical only of fused cast refractory (in contrast to pressed and sintered mixtures, including such sintered mixtures that are fired high enough to fuse only the crystalline boride, borocarbide and/or other phases having melting points lower than the free carbon or graphite so as to form a partial network or coating of these lower melting phases around separated grains of carbon or graphite).
  • This typically fused cast structure provides extremely tight bonding of all the phases that are not easily opened up at the boundaries, which is important for good corrosion resistance to gases and liquids put in contact with the refractory body. It also imparts good resistance to abrasion and/ or erosion by gases,
  • FIGURE 1 Example No. 3; FIGURE 2, Example No. 10; FIGURE 3, Example No. 13; FIGURE 4, Example No. 31; FIGURE 5, Example N0. 34; FIGURE 6, Example N0. 37; FIGURE 7, Example N0. 42; and FIGURE 8, Example No. 54.
  • the light or white areas are the randomly shaped and oriented boride, borocarbide, etc., crystals.
  • the dark gray and/or black areas are the intergrown network of free carbon or graphite. Irregular boundaries and interfingering between the light and dark areas is readily apparent in all the figures.
  • FIG. 1 For example, see 10 in FIGURE 1, 12 and 14 in FIGURE 2, 16 and 18 in FIGURE 3, 20 and 22 in FIGURE 4, 24 and 26 in FIGURE 5, 28 in FIGURE 6, 30 in FIGURE 7 (especially illustrative of sutured boundary) and 32 in FIG- URE 8.
  • FIGURES 3 and 4 can be seen typical illustrations of the larger graphite platelets 34 and 36.
  • Some of the smaller or finer elongated dark areas (for example see 38 in FIGURE 5 and 40 in FIG- URE 7) appear to be part of a eutectic structure or pos sibly exsolved (precipitated) graphite within the boride, borocarbide, etc., crystals.
  • FeTiO (ilmenite):
  • phase anlysis data were obtained from samples by the conventional techniques, such as the point count method or X-ray diffraction patterns and microscopic examinations.
  • the free carbon was found in these examples to be present as crystalline graphite (G).
  • the highly superior thermal shock resistance data are based on a severe test that involved cutting an approximately 1" x x /2" sample from each example, heating the sample to 1800 C. and then dropping the hot sample into water at room temperature. This procedure constitutes one cycle of this severe test. At the end of each cycle, the sample is examined for the occurrence of one or more thermal shock fractures. If none are found, the cycle is repeated until such fracturing is observed and the total number of cycles completed at that time are noted. However, no sample was subjected to more than eight cycles for economy purposes since no fracturing at the end of eight cycles in this test, is without doubt, indicative of highly superior thermal shock resistance. The samples that showed no fracturing at the end of eight cycles are noted as 8 cycles.
  • an identical sized sample of the commercial fused cast refractory that, to our knowledge, exhibited the highest degree of thermal shock resistance heretofore shattered into about three pieces on the second cycle in the above-described test.
  • Such commercial refractory is a fused and cast mixture of, by weight, 98.81% alumina, 0.52% quicklime and 0.67% fluorspar.
  • Another fused cast refractory that had previously been found to have relatively good thermal shock resistance is that of fused cast pure magnesium oxide casting having a crystalline texture consisting of at least 75 volume percent of equant, unoriented, periclase crystals with a majority of these crystals having a fine-to-medium grain size ranging from 20 to 5000 microns.
  • Identical sized samples of these magnesia castings shattered into two or three pieces on the first or second cycle of the same test.
  • Oxidation resistance was determined by heating samples for 16 hours at 1000 C., thereafter cooling them to room temperature and X-raying them to determine the presence of oxide phase in quantity greater than in the original sample before testing. Substantially no increase in oxide phase content was indicative of excellent oxidation resistance while a very minor amount of increased oxide (e.g. TiO ZrO etc.) was denoted as very good resistance, and ratings of good, fair and poor were indicative of increasing greater amounts of increased oxide up to predominant quantities thereof for a poor rating.
  • the high degree of oxidation resistance appears tobe at least partly the result of a thin, boron oxide-rich, glassy film forming on the external surfaces of the body, which film retards further oxidation of the body. From such testing, it was noted that an amount of at least 10% by weight boron was necessary to consistently assure good oxidation resistance.
  • test was conducted for examples of this invention as well as of prior art materials, two of which are more commonly used for basic oxygen furnace linings.
  • the test comprised placing 1 /2 x l x /2 samples in a gasoxygen furnace adapted to approximate the temperature and reducing atmosphere of a basic oxygen furnace.
  • the samples were passed, with one of their largest surfaces facing upward, through a downwardly directed stream of molten high-lime basic ferruginous slag droplets at a substantially uniform rate of 60 times per hour until 2 kilograms of slag had been employed.
  • the slag was representative of basic oxygen furnace slag developed during the production of a heat of steel and had the following composition, by weight: 23.75% Fe O 25.94% SiO 40.86% CaO, 6.25% MgO and 3.20% A1 0
  • the average thickness of the samples was measured and compared with the original /2" thickness. The results are expressed as a percentage change in thickness (called percent slag cut).
  • the refractory product of this invention has also exhibited good resistance to attack by molten iron as demonstrated by the results of two tests utilizing the same size of sample as employed in the above-described slag re sistance test and the percent Fe cut is determined in the same manner as the percent slag cut.
  • the other molten iron test was identical to the slag resistance test noted above except that the test was conducted at 1600 C. with the samples passed through a downwardly directed stream of molten iron instead of molten slag. The results of this test are noted in the table by the symbol (R) immediately following the values of percent Fe cut.
  • the free carbon or praphite can be as low as 2% by weight, this limit tends to include some fused cast bodies or products possessing only minimal improvement in thermal shock resistance that is possible with this invention.
  • the free carbon or graphite content should be at least 7%.
  • Bodies with graphite or free carbon in excess of 40% (or in some cases only greater than 20%) by weight are particularly unique in that they are comparable to pure graphite for many applications, but without certain disadvantages of the latter material.
  • these very high graphite content bodies are superior to pure graphite in that they have greater oxidation resistance, greater corrosion and/or erosion resistance and greater strength.
  • these monolithic bodies can be said to be composed of an alloy of essentially carbon, boron and the above-noted metallic substances.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of metallic boride, metallic borocarbide and mixtures thereof, said refractory analytically comprising essentially: 1) carbon; (2) more than 5% by weight of boron; (3) more than 5% by Weight of metallic substance selected from the group consisting of titanium, zirconium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten, silicon, mixtures of the foregoing first group of metallic elements alone, and mixtures of at least one first group metallic element plus at least one second group metallic element selected from the group consisting of manganese, iron, cobalt and nickel provided the content of the second group elements is not greater than 50% by weight of the total metallic substance content; (4) 0 to 15% by weight of at least one dilu
  • a fused cast refractory consisting essentially of at least 7% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of metallic boride, metallic borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of metallic substance selected from the group consisting of titanium, zirconium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten, silicon, mixtures of the foregoing first group of metallic elements alone, and mixtures of at least one first group metallic element plus at least one second group metallic element selected from the group consisting of manganese, iron, cobalt and nickel provided the content of the second group elements is not greater than 50% by Weight of the total metallic substance content; (4) 0 to 10% by Weight of at least one diluent selected
  • a fused cast refractory consisting essentially of at least 2% by Weight of free carbon in the form of an intergrown network intermingling and interlocking withsubstatially randomly oriented crystals including crystals selected from the group consisting of titanium boride, titanium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of titanium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of zirconium boride, zirconium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight'of boron; (3) at least 10% by weight of zirconium, (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by Weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of hafnium boride, hafnium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by Weight of hafnium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of vanadium boride, vanadium borocarbide and 13 mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of vanadium; (4) O to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of to by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of niobium boride, niobium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least by weight of boron; (3) at least 10% by weight of niobium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any, of O to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of tantalum boride, tantalum borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of tantalum; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of chromium boride, chromium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of chromium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by Weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of molybdenum boride, molybdenum borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) at least 10% by weight of molybdenum; (4) 0 to 10% by Weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of tungsten boride, tungsten borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by Weight of boron; (3) at least 10% by weight of tungsten; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of silicon boride, silicon borocarbide and mix- 14 tures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3) greater than 5% by weight of silicon; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of titanium boride, chromium boride, titanium-chromium boride, titanium borocarbide, chromium borocarbide, titanium-chromium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by Weight of boron; (3a) at least 10% by Weight of titanium; (3b) at least 1% by weight of chromium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of titanium boride, iron boride, titaniumiron boride, titanium borocarbide, iron borocarbide, titanium-iron borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3a) at least 10% by weight of titanium; (3b) at least 2% by weight of iron; (4) 0 to 10% by Weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any, of O to 5% by Weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of zirconium boride, chromium boride, zirconium-chromium boride, zirconium borocarbide, chromium borocarbide, zirconium-chromium borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3a) at least l0% by weight of zirconium; (31)) at least 1% by weight of chromium; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5) a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the groups consisting of zirconium boride, .silicon boride,
  • zirconium-silicon boride zirconium borocarbide, silicon borocarbide, zirconium-silicon borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by weight of boron; (3a) at least 10% by weight of zirconium; (3b) at least 3% by weight of silicon; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any, of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of tantalum boride, niobium boride, tantalum-niobium boride, tantalum borocarbide, niobium borocarbide, tantalum-niobium borocarbide and mixtures thereof, said refractory analytically comprising essentially:
  • a fused cast refractory consisting essentially of at least 2% by weight of free carbon in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of simple boride, complex-boride, simple borocarbicle and complex borocarbide of titanium, chromium and iron and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least by Weight of boron; (3a) at least 10% by weight of titanium; (3b) at least 1% by Weight of chromium; (30) at least 2% by weight of iron; (4) 0 to 10% by weight of at least one diluent selected from the group consisting of oxygen and nitrogen; and (5 a remainder, if any of 0 to 5% by weight of other elements.
  • a fused cast refractory consisting essentially of more than by weight graphite in the form of an intergrown network inter mingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of metallic boride, metallic borocarbide and mixtures thereof, said refractory analytically com prising essentially: (1) carbon; (2) at least 10% by weight boron; (3) at least 10% by weight of metallic substance selected from the group consisting of titanium, zirconium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten, silicon, mixtures of the foregoing first group of metallic elements alone, and mixtures of at least one first group metallic element plus at least one second group metallic element selected from the group consisting of manganese, iron, cobalt and nickel provided the content of'the second group elements is not greater than 50% by weight of the total metallic substance content; (4) 0 to 10% by weight of at least one diluent
  • a fused cast refractory consisting essentially of more than 40% by weight graphite in the form of an intergrown network intermingling and interlocking with substantially randomly oriented crystals including crystals selected from the group consisting of metallic boride, metallic borocarbide and mixtures thereof, said refractory analytically comprising essentially: (1) carbon; (2) at least 10% by Weight boron; (3) at least 10% by Weight of metallic substance selected from the group consisting of titanium, zirconium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum, tungsten, silicon, mixtures of the foregoing first group of metallic elements alone, and mixtures of at least one first group metallic element plus at least one second group metallic element selected from the group consisting of manganese, iron, cobalt and nickel provided the content of the second group elements is not greater than by weight of the total metallic substance content; (4) 0 to v10% by weight of at least one diluent

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  • Engineering & Computer Science (AREA)
  • Ceramic Engineering (AREA)
  • Manufacturing & Machinery (AREA)
  • Materials Engineering (AREA)
  • Organic Chemistry (AREA)
  • Structural Engineering (AREA)
  • Inorganic Chemistry (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Ceramic Products (AREA)
  • Compositions Of Oxide Ceramics (AREA)
  • Manufacture And Refinement Of Metals (AREA)
  • Discharge Lamp (AREA)
  • Organic Low-Molecular-Weight Compounds And Preparation Thereof (AREA)
  • Furnace Housings, Linings, Walls, And Ceilings (AREA)
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US434812A 1965-02-24 1965-02-24 Fused cast refractory Expired - Lifetime US3340077A (en)

Priority Applications (9)

Application Number Priority Date Filing Date Title
US434812A US3340077A (en) 1965-02-24 1965-02-24 Fused cast refractory
NO159550A NO119468B (ja) 1965-02-24 1965-08-31
GB37371/65A GB1101854A (en) 1965-02-24 1965-09-01 Fused cast refractory
NL6511776A NL6511776A (ja) 1965-02-24 1965-09-09
AT829765A AT276203B (de) 1965-02-24 1965-09-10 Feuerfester Schmelzgußkörper aus Metallborid oder Metallborcarbid
DE19651571358 DE1571358A1 (de) 1965-02-24 1965-09-10 Feuerfeste Schmelzgussmassen
SE11847/65A SE305621B (ja) 1965-02-24 1965-09-10
BE669498D BE669498A (ja) 1965-02-24 1965-09-10
ES0317367A ES317367A1 (es) 1965-02-24 1965-09-11 Mejoras relacionadas con la proporcion de un material refractario vaciado en estado fundido.

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
US434812A US3340077A (en) 1965-02-24 1965-02-24 Fused cast refractory

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US3340077A true US3340077A (en) 1967-09-05

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US434812A Expired - Lifetime US3340077A (en) 1965-02-24 1965-02-24 Fused cast refractory

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US (1) US3340077A (ja)
AT (1) AT276203B (ja)
BE (1) BE669498A (ja)
DE (1) DE1571358A1 (ja)
ES (1) ES317367A1 (ja)
GB (1) GB1101854A (ja)
NL (1) NL6511776A (ja)
NO (1) NO119468B (ja)
SE (1) SE305621B (ja)

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3770487A (en) * 1971-01-28 1973-11-06 Mc Donnell Douglas Corp Refractory composites
US3871835A (en) * 1969-04-21 1975-03-18 Onera (Off Nat Aerospatiale) Refractory composite alloys containing rod-like and/or platelet-like lamellae
US4029000A (en) * 1972-12-28 1977-06-14 Toshiba Kikai Kabushiki Kaisha Injection pump for injecting molten metal
US4076506A (en) * 1975-10-14 1978-02-28 E. I. Du Pont De Nemours And Company Transition metal carbide and boride abrasive particles
US4333813A (en) * 1980-03-03 1982-06-08 Reynolds Metals Company Cathodes for alumina reduction cells
US4379852A (en) * 1980-08-26 1983-04-12 Director-General Of The Agency Of Industrial Science And Technology Boride-based refractory materials
RU2622276C2 (ru) * 2015-07-27 2017-06-13 Федеральное государственное бюджетное учреждение науки Институт структурной макрокинетики и проблем материаловедения Российской академии наук Керамический композит и шихта для его получения

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
None *

Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3871835A (en) * 1969-04-21 1975-03-18 Onera (Off Nat Aerospatiale) Refractory composite alloys containing rod-like and/or platelet-like lamellae
US3770487A (en) * 1971-01-28 1973-11-06 Mc Donnell Douglas Corp Refractory composites
US4029000A (en) * 1972-12-28 1977-06-14 Toshiba Kikai Kabushiki Kaisha Injection pump for injecting molten metal
US4076506A (en) * 1975-10-14 1978-02-28 E. I. Du Pont De Nemours And Company Transition metal carbide and boride abrasive particles
US4333813A (en) * 1980-03-03 1982-06-08 Reynolds Metals Company Cathodes for alumina reduction cells
US4379852A (en) * 1980-08-26 1983-04-12 Director-General Of The Agency Of Industrial Science And Technology Boride-based refractory materials
RU2622276C2 (ru) * 2015-07-27 2017-06-13 Федеральное государственное бюджетное учреждение науки Институт структурной макрокинетики и проблем материаловедения Российской академии наук Керамический композит и шихта для его получения

Also Published As

Publication number Publication date
BE669498A (ja) 1966-03-10
ES317367A1 (es) 1966-06-01
AT276203B (de) 1969-11-25
NO119468B (ja) 1970-05-19
NL6511776A (ja) 1966-08-25
GB1101854A (en) 1968-01-31
SE305621B (ja) 1968-10-28
DE1571358A1 (de) 1971-02-18

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